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RootBrent.c
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RootBrent.c
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/*
* SUMMARY: RootBrent.c - Determine surface temperature iteratively
* USAGE: Part of DHSVM
*
* AUTHOR: Bart Nijssen
* ORG: University of Washington, Department of Civil Engineering
* E-MAIL: [email protected]
* ORIG-DATE: Apr-96
* DESCRIPTION: Determine surface temperature iteratively using the Brent
* method.
* DESCRIP-END.
* FUNCTIONS: RootBrent()
* COMMENTS:
* $Id: RootBrent.c,v 1.4 2003/07/01 21:26:23 olivier Exp $
*/
#include <math.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "settings.h"
#include "brent.h"
#include "massenergy.h"
#include "functions.h"
#include "DHSVMerror.h"
/*****************************************************************************
GENERAL DOCUMENTATION FOR THIS MODULE
-------------------------------------
Source: Brent, R. P., 1973, Algorithms for minimization without derivatives,
Prentice Hall, Inc., Englewood Cliffs, New Jersey
Chapter 4
This source includes an implementation of the algorithm in ALGOL-60, which
was translated into C for this application.
The method is also discussed in:
Press, W. H., S. A. Teukolsky, W. T. Vetterling, B. P. Flannery, 1992,
Numerical Recipes in FORTRAN, The art of scientific computing,
Second edition, Cambridge University Press
(Be aware that this book discusses a Brent method for minimization (brent),
and one for root finding (zbrent). The latter one is similar to the one
implemented here and is also copied from Brent [1973].)
The function returns the surface temperature, TSurf, for which the sum
of the energy balance terms is zero, with TSurf in the interval
[MinTSurf, MaxTSurf]. The surface temperature is calculated to within
a tolerance (6 * MACHEPS * |TSurf| + 2 * T), where MACHEPS is the relative
machine precision and T is a positive tolerance, as specified in brent.h.
The function assures that f(MinTSurf) and f(MaxTSurf) have opposite signs.
If this is not the case the program will abort. In addition the program
will perform not more than a certain number of iterations, as specified
in brent.h, and will abort if more iterations are needed.
******************************************************************************/
/*****************************************************************************
Function name: RootBrent()
Purpose : Calculate the surface temperature in the absence of snow
Required :
int y - Row number of current pixel
int x - Column number of current pixel
float LowerBound - Lower bound for root
float UpperBound - Upper bound for root
float (*Function)(float Estimate, va_list ap)
... - Variable arguments
The number and order of arguments has to be
appropriate for the Function pointed to, since
the list of arguments after Nargs will be passed
on to Function.
See the appropriate Function for the correct
arguments.
Returns :
float b - Effective surface temperature (C)
Modifies : none
Comments :
*****************************************************************************/
float RootBrent(int y, int x, float LowerBound, float UpperBound,
float (*Function) (float Estimate, va_list ap), ...)
{
const char *Routine = "RootBrent";
char ErrorString[MAXSTRING + 1];
va_list ap; /* Used in traversing variable argument list
*/
float a;
float b;
float c;
float d;
float e;
float fa;
float fb;
float fc;
float m;
float p;
float q;
float r;
float s;
float tol;
int i;
int j;
int eval = 0;
sprintf(ErrorString, "%s: y = %d, x = %d", Routine, y, x);
/* initialize variable argument list */
a = LowerBound;
b = UpperBound;;
va_start(ap, Function);
fa = Function(a, ap);
eval++;
va_start(ap, Function);
fb = Function(b, ap);
eval++;
/* if root not bracketed attempt to bracket the root */
j = 0;
while ((fa * fb) >= 0 && j < MAXTRIES) {
a -= TSTEP;
b += TSTEP;
va_start(ap, Function);
fa = Function(a, ap);
eval++;
va_start(ap, Function);
fb = Function(b, ap);
eval++;
j++;
}
if ((fa * fb) >= 0) {
ReportError(ErrorString, 34);
}
fc = fb;
for (i = 0; i < MAXITER; i++) {
if (fb * fc > 0) {
c = a;
fc = fa;
d = b - a;
e = d;
}
if (fabs(fc) < fabs(fb)) {
a = b;
b = c;
c = a;
fa = fb;
fb = fc;
fc = fa;
}
tol = 2 * MACHEPS * fabs(b) + T;
m = 0.5 * (c - b);
if (fabs(m) <= tol || fequal(fb, 0.0)) {
va_end(ap);
return b;
}
else {
if (fabs(e) < tol || fabs(fa) <= fabs(fb)) {
d = m;
e = d;
}
else {
s = fb / fa;
if (fequal(a, c)) {
/* linear interpolation */
p = 2 * m * s;
q = 1 - s;
}
else {
/* inverse quadratic interpolation */
q = fa / fc;
r = fb / fc;
p = s * (2 * m * q * (q - r) - (b - a) * (r - 1));
q = (q - 1) * (r - 1) * (s - 1);
}
if (p > 0)
q = -q;
else
p = -p;
s = e;
e = d;
if ((2 * p) < (3 * m * q - fabs(tol * q)) && p < fabs(0.5 * s * q))
d = p / q;
else {
d = m;
e = d;
}
}
a = b;
fa = fb;
b += (fabs(d) > tol) ? d : ((m > 0) ? tol : -tol);
va_start(ap, Function);
fb = Function(b, ap);
eval++;
}
}
ReportError(ErrorString, 33);
}